2019年第80回応用物理学会秋季学術講演会

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10 スピントロニクス・マグネティクス » 10 スピントロニクス・マグネティクス(ポスター)

[18p-PB1-1~84] 10 スピントロニクス・マグネティクス(ポスター)

2019年9月18日(水) 13:30 〜 15:30 PB1 (第二体育館)

13:30 〜 15:30

[18p-PB1-79] Ab initio calculated optical and magneto-optical properties of M/Fe (M=Cu, Ag, Au) superlattices

〇(D)Muhammad Arifin1、Abdul-Muizz Pradipto1、Toru Akiyama1、Tomonori Ito1、Kohji Nakamura1 (1.Mie University)

キーワード:density functional theory, optical conductivity, Kerr rotation

Surface Plasmon Resonance (SPR) has been applied in various fields as sensors. One of the crucial issues on the applicability of SPR is the sensitivity of SPR, which should be optimized by properly designing the structures and properties of the sensing layer. Ferromagnetic materials that have large magneto-optical (MO) properties are good candidates for sensing layer as the resulting magneto-optical activity may lead to sensitivity enhancement [1-4]. Among the crucial ingredients for a high MO response are a large Kerr rotation and zero ellipticity. In the present work, by using first principle-density functional theory calculations [5], we study the optical and magneto-optical properties in Cu/Fe, Ag/Fe and Au/Fe superlattice. We particularly focus on the quality factor and Kerr rotation angle which are directly related to the SPR applications. At low energy levels (<2 eV), quality factor in the noble-metal/Fe system increases compared to Fe-bulk and has a peak at the energy of around 1 eV. At 632 nm, the quality factor in the noble-metal/Fe system increases 3 times. Furthermore, the increase in the Kerr rotation only occurs in the Au/Fe system with peaks at energy levels of 4.6 eV and 8.2 eV. The increase of Kerr rotation is due to the decreased the diagonal component of optical conductivity (σxx) and larger the off-diagonal component of optical conductivity (σxy) [6]. We also studied the spin and orbital magnetic moments and their correlations with (σxy). The highest increase in the spin-orbit correlation SzLz is found in Au/Fe system. Further discussions will be presented.
Keywords: density functional theory, optical conductivity, Kerr rotation